SILICON CARBIDE CERAMIC MEMBRANE SYSTEMS

Hardcore Filtration Under Extreme Operating Conditions

BSLF's Silicon Carbide (SiC) Ceramic Membrane Modules are available in two types: plate and tubular. They are high-efficiency separation membranes with silicon carbide (SiC) ceramic materials as the core filtration medium. Relying on the porous structure and chemical inertness of the silicon carbide material, they can maintain stable filtration accuracy and permeation efficiency even under extreme working conditions such as high-temperature environments, strong acid-base environments, high-intensity environments, and high-salt environments. They are key equipment in fields such as the advanced treatment of industrial wastewater and the purification of chemical materials.

BSLF's Silicon Carbide (SiC) Ceramic Membrane Systems are designed in a modular manner, featuring filtration, separation and cleaning functions. They have compact structures and a high degree of automation.

Based on the raw water quality and treatment capacity, we provide full-process customized services covering membrane modules, equipment specifications, and intelligent control.

NANO-MODIFIED ULTRAFILTRATION SYSTEMS

Nano-Modification for Enhanced Energy Efficiency

BSLF's Nano-Modified Ultrafiltration Modules are a new type of ultrafiltration separation membrane modules. The nanostructure and chemical properties of modified materials optimize the filtration performance of membrane modules, with balanced performance in particle interception, fouling resistance and stable permeate flux. They are widely used in drinking water purification, industrial wastewater treatment and material separation.

BSLF's Nano-Modified Ultrafiltration Systems integrate filtration, separation, gas cleaning and liquid cleaning functions, and adopt intelligent operation mode. Compared with conventional ultrafiltration equipment, the systems inherit reliable interception performance and achieve upgraded fouling resistance and durability. Meanwhile, they feature low energy consumption and manageable operation and maintenance costs, and can well adapt to long-term stable operation under various application scenarios.

Based on the raw water quality and treatment capacity, we provide full-process customized services covering membrane modules, equipment specifications, and intelligent control.

REVERSE OSMOSIS SYSTEMS

Deep Purification

BSLF's Reverse Osmosis (RO) Systems are high-efficiency desalination and purification equipment that utilize the selective permeability of semi-permeable membranes to separate water from solutes under pressure driving. These systems can effectively remove impurities such as ions, organic substances and microorganisms from the water, and are widely used in fields including seawater desalination, ultrapure water preparation, and advanced industrial wastewater treatment.

BSLF's Reverse Osmosis (RO) Systems are mainly divided into two types: brackish water reverse osmosis systems and seawater reverse osmosis systems. Adopting a modular design, the systems feature high desalination efficiency, good effluent water quality, and high automation level.

Based on the raw water quality, treatment capacity, and target water quality, we provide full-process customized services covering reverse osmosis membrane models, equipment specifications, and intelligent control, and offer tailored solutions for you.

ELECTRODIALYSIS REVERSAL SYSTEMS

Break Through the Scaling Bottleneck to Achieve Efficient and Stable Desalination

BSLF's Electrodialysis Reversal (EDR) Stacks are high-efficiency desalination and water purification equipment. Their core feature is the regular switching of electrode polarity, which effectively solves the membrane scaling problem of traditional electrodialysis equipment, improves system stability and operating efficiency, and is widely used in fields such as brackish water desalination, industrial wastewater treatment, and reclaimed water reuse.

BSLF's EDR Stacks adopt special electrodes, and the matched ion exchange membranes have the advantages of large exchange capacity, low resistance, and use persistence. With reasonable separator and flow channel design, they are not prone to scaling and also feature high desalination efficiency and low energy consumption.

BSLF's EDR Systems adopt a modular design, have the advantages of reasonable structure, intelligent control, and stable operation, and are suitable for long-term operation needs in multiple scenarios.

Based on the raw water quality, treatment capacity, and target water quality, we provide full-process customized services ranging from electrode matching, ion exchange membrane selection, and equipment specifications to intelligent control, ensuring the solution is accurately tailored.

BIPOLAR MEMBRANE ELECTRODIALYSIS SYSTEMS

Resource Recycling, Cost Reduction and Efficiency Improvement

BSLF's Bipolar Membrane Electrodialysis (BPED) Stacks integrate the water dissociation characteristics of bipolar membranes and traditional electrodialysis technology, and are new-type water treatment equipment. Under the action of an electric field, they realize salt separation and in-situ generation of acids and alkalis, and have the functions of desalination, purification and resource recovery. They are widely used in the separation of high-value-added substances and wastewater resource treatment in fields such as new energy and chemical industry.

BSLF's BPED Stacks adopt high-performance bipolar membranes, with the advantages of high water dissociation efficiency and acid-alkali resistance.

BSLF's BPED Systems adopt a modular design, with the characteristics of reasonable structure, intelligent control, low energy consumption and stable operation, and are suitable for long-term operation in multiple scenarios.

Based on the raw water quality, treatment capacity, and target water quality, we provide full-process customized services ranging from electrode matching, bipolar membrane selection, ion exchange membrane selection, and equipment specifications to intelligent control, tailoring the suitable solutions.